A substrate processing apparatus includes a placing table, having a placing surface on which a processing target substrate is placed, provided with a gas supply line through which a heat transfer gas is supplied into a gap between the processing target substrate and the placing surface; and a gas supply system configured to generate the heat transfer gas to be supplied into the gap between the processing target substrate and the placing surface through the gas supply line by mixing a heat transfer gas having a relatively low temperature and a heat transfer gas having a relatively high temperature.

The present disclosure generally relates to plasma assisted or plasma enhanced processing chambers. More specifically, embodiments herein relate to electrostatic chucking (ESC) substrate supports configured to provide independent pulses of DC voltage through a switching system to electrodes disposed through the ESC substrate support, or to electrodes disposed on a surface of the ESC, or to electrodes embedded in the ESC substrate support. The switching system can independently alter the frequency and duty cycle of the pulsed DC voltage that is coupled to each electrode. During processing of the substrate, the process rate, such as etch rate or deposition rate, can be controlled independently in regions of the substrate because the process rate is a function of the frequency and duty cycle of the pulsed DC voltage. The processing uniformity of the process performed on the substrate is improved.

Apparatuses and methods are provided for manufacturing diamond electronic devices. The apparatus includes a base comprising a water-block and a cover that at least partially covers the water-block. The apparatus includes a sample stage disposed on the base. The apparatus further includes a sample holder disposed on the sample stage and configured to accept a diamond substrate. The apparatus includes controlled thermal interfaces between water-block, sample stage, sample holder and diamond substrate.

Apparatuses and methods are provided for manufacturing diamond electronic devices. The apparatus includes a base comprising a water-block and a cover that at least partially covers the water-block. The apparatus includes a sample stage disposed on the base. The apparatus further includes a sample holder disposed on the sample stage and configured to accept a diamond substrate. The apparatus includes controlled thermal interfaces between water-block, sample stage, sample holder and diamond substrate.

A substrate retaining apparatus, a load lock assembly comprising the substrate retaining apparatus, and a system including the substrate retaining apparatus are disclosed. The substrate retaining apparatus can include at least one sidewall and one or more heat shields. One or more of the at least one sidewall can include a cooling fluid conduit to facilitate cooling of substrates retained by the substrate retaining apparatus. Additionally or alternatively, one or more of the at least one sidewall can include a gas conduit to provide gas to a surface of a retained substrate.

A placement apparatus is provided in the present disclosure. The apparatus includes a stage on which a substrate is placed; a support configured to support the stage from a side of a rear surface of the stage that is opposite to a placement surface on which the substrate is placed; a temperature adjustment member including a plate securing the stage from a lower surface of the stage, a shaft extending downwards from the plate, and a hole accommodating the support through the shaft from the plate, and being capable of a temperature adjustment; a heat-insulating member disposed between the stage and the temperature adjustment member; and an abutment member configured to abut the substrate placed on the stage.

The present disclosure provides a carrying device and a semiconductor processing apparatus. The carrying device includes a heating plate and a cooling plate, the heating plate and the cooling plate are spaced apart, and a thermal insulation region is formed between the heating plate and the cooling plate. The carrying device of the present disclosure not only can preempt the need to stop the process due to excessively high temperature, but also can maintain a uniform and stable temperature throughout the process, thereby providing a qualified and stable processing temperature for a workpiece to be processed, and eventually obtaining better processing results.

In a processing method according to one exemplary embodiment, a first nitrified region of a workpiece is etched. The first nitrified region is provided on a first protrusion made of silicon. The workpiece further has a second protrusion, a second nitrified region, and an organic region. The second protrusion is made of silicon. The second nitrified region contains silicon and nitrogen and is provided on the second protrusion. The organic region covers the first and second protrusions and the first and second nitrified regions. In the processing method, the organic region is partially etched to expose the first nitrified region. Then, a silicon oxide film is formed to cover the surface of an intermediate product produced from the workpiece. Then, the silicon oxide film is etched to expose an upper surface of the first nitrified region. Then, the first nitrified region is isotropically etched.

An epitaxial deposition chamber having an upper cone for controlling air flow above a dome in the chamber, such as a high growth rate epitaxy chamber, is described herein. The upper cone has first and second components separated by two or more gaps in the chamber, each component having a partial cylindrical region having a first concave inner surface, a first convex outer surface, and a fixed radius of curvature of the first concave inner surface, and a partial conical region extending from the partial cylindrical region, the partial conical region having a second concave inner surface, a second convex outer surface, and a varying radius of curvature of the second concave inner surface, wherein the second concave inner surface extends from the partial cylindrical region to a second radius of curvature less than the fixed radius of curvature.

A glass laminate includes a glass substrate including a first main surface and a second main surface, an antireflection layer on at least one of the first main surface and the second main surface, and an antifouling layer on the antireflection layer. The antireflection layer includes at least one low refractive index layer and at least one high refractive index layer, and the low refractive index layer and the high refractive index layer being alternately laminated. The antireflection layer includes an outermost layer farthest from the glass substrate and the outermost layer is the low refractive index layer including SiO.sub.2 as a main component. A distribution of fluorine concentration in a thickness direction of the outermost layer, measured by secondary ion mass spectrometry, has a peak.